Effect of cadmium (Cd) and lead (Pb) soil contamination on the development of Hymenoscyphus fraxineus on Fraxinus excelsior and F. angustifolia seedlings

doi:10.3832/ifor4322-016

Effect of cadmium (Cd) and lead (Pb) soil contamination on the development of Hymenoscyphus fraxineus on Fraxinus excelsior and F. angustifolia seedlings

iForest - Biogeosciences and Forestry, Volume 16, Issue 6, Pages 307-313 (2023)
doi: https://doi.org/10.3832/ifor4322-016
Published: Nov 09, 2023 - Copyright © 2023 SISEF

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In light of the increase of environmental pollution, we tested the effect of cadmium (Cd) and lead (Pb) soil contamination on ash dieback. The experiment included the inoculation of Hymenoscyphus fraxineus on Fraxinus excelsior and Fraxinus angustifolia seedlings growing on unpolluted soil, soil contaminated with cadmium (Cd), and soil contaminated with lead (Pb). At the end of the experiment, 173 days after soil contamination and 50 days since inoculation, all F. excelsior and F. angustifolia seedlings inoculated with H. fraxineus showed ash dieback symptoms in comparison to their control groups. However, both F. excelsior and F. angustifolia seedlings grown on contaminated soil had significantly increased necrotic lesions in comparison to the seedlings grown on uncontaminated soil. Our results showed for the first time that cadmium (Cd) and lead (Pb) soil contamination can significantly contribute to ash dieback and increase damage to F. excelsior and F. angustifolia seedlings.

Soil Contamination, Cadmium (Cd), Lead (Pb), Fraxinus excelsior

Ash dieback caused by the invasive fungus Hymenoscyphus fraxineus Baral, Queloz, and Hosoya (Kowalski) is a main threat to the preservation of common ash (Fraxinus excelsior L.) and narrow-leaved ash (Fraxinus angustifolia Vahl) in Europe ([37], [15]). Fungus forms numerous inoculum which is easily transferred between different areas and the strategies aimed at removing infected trees and forming quarantine zones do not show to be efficient in disease suppression ([4]). Many studies showed that Fraxinus angustifolia is slightly less sensitive to dieback than F. excelsior ([12]), while one study showed the opposite results ([1]). Hymenoscyphus fraxineus pathogen is tolerant to a wide range of environmental conditions ([15]) whereby the fungus virulence remains high even in populations that have been present in some areas for a long time ([23]). However, the influence of several environmental conditions, such as site, stand, and climate conditions, on the development or spread of this pathogen has been studied ([3], [15], [38], [24], [17], [14], [19], [47]). Understanding the machanism of plant tolerance to pathogens and other harmful factors is particularly important in the context of global warming, where the pollutant mobility in the environment is intensively increasing ([28]). For example, environmental pollution with cadmium and lead has become a global problem ([7]).

The harmful effects of cadmium on plants are reflected in the disruption of stomatal closure, inhibition of nutrient uptake, reduction of enzyme activities, and disruptions in photosynthesis and respiration, which can lead to cell structure disruptions and mutagenic effects ([20]). Lead has also a harmful effect on plants cells as it hinders the cell absoprtion of potassium, calcium, magnesium, copper, or iron, damages cell organelles, and causes reactive oxygen species that further damage nucleic acids, lipids, and proteins ([20]). Plants have detoxification mechanisms that protect them to some extent from the negative effects of heavy metals. Indeed, the heavy metal effects on plants are related to their dose as well as to the type and developmental stage of the plant ([48], [28]). There is a large amount of data on the detoxification mechanisms of plants from cadmium and lead ([29], [31]).

Although heavy metals in high concentrations have a harmful effect on all organisms, smaller doses of heavy metals can stimulate the physiological processes of pathogens (i.e., show a hormetic effect), though further studies are needed to understand their effect on pathogenicity/virulence ([13]). These studies are particularly important for Hymenoscyphus fraxineus because little knowledge is currently available on the influence of environmental factors on the development of this pathogen, thereby improving measures to recover and protect infected F. excelsior and F. angustifolia trees in habitats contaminated with heavy metals. In most European countries, the concentration of Cd in forest floor indicates that deposition is the main transfer route, with average concentrations for forest topsoil ranging around 0.09 mg kg^-1, ranging from a minimum of 0.02 to a maximum of 3.17 mg kg^-1 ([45], [6]). In European forest soils, lead also shows high levels of deposition, with average concentration in the forest topsoil of 15.3 mg kg^-1 and ranging from 1.63 to 151.12 mg kg^-1 ([45], [6]). In general, there is a great variability in concentrations of these elements among the European countries, whereby in forest floor cadmium values range from 0.40 to 0.65 mg kg^-1 and lead from 40 to 65 mg kg^-1 ([6]). Compared to the previously established critical values of heavy metals in soil ([44]) current average values are only few to several tens of times smaller than the critical thresholds.

Following the above-mentioned, the objectives of this research were to (i) examine the influence of soil contamination with cadmium and lead on Hymenoscyphus fraxineus development on two-year-old seedlings of Fraxinus excelsior and Fraxinus angustifolia; (ii) examine the difference in the influence of lead and cadmium on Hymenoscyphus fraxineus development on two-year seedlings of F. excelsior and F. angustifolia; (iii) examine the difference in H. fraxineus development on two-year-old seedlings of F. excelsior and F. angustifolia grown on soil contaminated with cadmium or lead. The tested null hypotheses were: (i) there is no difference in the development of H. fraxineus grown in uncontaminated soil and soil contaminated with cadmium or lead; (ii) there is no difference in the influence of cadmium and lead on the development of H. fraxineus; (iii) there is no difference in the development of H. fraxineus between F. excelsior and F. angustifolia seedlings grown on soil contaminated with cadmium or lead.

Plant and soil material

A total of 300 seedlings of two-year-old F. excelsior and F. angustifolia were used for the experiment. Soil (3.8% coarse sand 0.2-2 mm; 25.50% fine sand 0.02-0.2 mm; 35.10% dust 0.002-0.02 mm; 35.6% clay particles < 2 μm; 29.30% total sand 0.02-2 mm; 70.70% total clay < 0.02 mm; 6.62% organic matter) was collected at the location Obrenovac (44° 39′ 58″ N, 20° 13′ 56″ E - Fig. 1). A total of 150 F. excelsior and 150 F. angustifolia seedlings were planted in plastic bags filled with 1.8 kg of the above soil at the end of the 2021 growing season. Seedlings of F. excelsior belonged to a Western Serbia provenance and seedlings of F. angustifolia were from a Central Hungary provenance. At the beginning of the experiment, the average height (H) of seedlings was 90.5 ± 17 cm and 96 ± 22 cm for F. excelsior and F. angustifolia, respectively.

Fig. 1 - The location from which the soil was collected.

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The experiment was carried out under controlled conditions. The planted seedlings were kept in a closed climate chamber with a temperature range of 25-35 °C in the period before inoculation and 15-25 °C during and after inoculation.

Soil contamination

The soil was artificially contaminated with cadmium and lead during the 2022 growing season, using cadmium nitrate tetrahydrate (Cd(NO₃₎₂×4H₂O) and lead nitrate (Pb(NO₃₎₂). Hence, treatments included uncontaminated soil, cadmium-contaminated soil, and lead-contaminated soil.

Thresholds of cadmium or lead-contaminated soil are 3.5 mg kg^-1 Cd and 500 mg kg^-1 Pb in the organic layer ([44]) or 2 mg kg^-1 Cd and 200 mg kg^-1 Pb for multifunctional land use ([10]). The remediation value of heavy metals in the soil was calculated using the formula ([10], [34] - eqn. 1):

\begin{equation} (SW, IW)b = (SW, IW)sb \cdot {\frac{A + (B \cdot \text{%} clay) + (C \cdot \text{%}OM)}{ A+ (B \cdot 25)+(c \cdot 10) }} \end{equation}

where (SW, IW)b is the corrected remediation value for a specific soil, (SW, IW)sb is the heavy metal remediation value for a standard soil (for cadmium (SW, IW)sb = 12 mg kg^-1 ; for lead (SW, IW)sb = 530 mg kg^-1); %clay is the measured percentage of clay in a specific soil (particle size < 2 μm); %OM is the measured percentage of organic matter in a specific soil; and A, B, C are constants depending on the type of metal (for cadmium A = 0.4, B = 0.007, C = 0.021; for lead A = 50, B = 1, C = 1).

Each plastic bag, filled with 1.8 kg of soil, was injected with an amount of 51.52 mg of cadmium nitrate tetrahydrate or 1654.4 mg of lead nitrate dissolved in 20 ml of distilled water to achieve an amount of 12.05 mg kg^-1 (21.29 mg/1.8 kg) for cadmium, and 575.02 mg kg^-1 (1035.03 mg/1.8kg) for lead.

After planting, the soil of all treatments, including the inoculated and control seedlings, was watered identically with distilled, demineralized water three times a week during the first three weeks after contamination. Later, until the end of the experiment, the soil was watered with tap water, two to four times a week. Watering was carefully done to avoid water drainage from the bags and leaching of heavy metals from the substrate.

Inoculation test

A test of inoculation under the bark with Hymenoscyphus fraxineus was carried out four months after the addition of cadmium nitrate tetrahydrate and lead nitrate to soil. Fifty seedlings from each tree species were randomly chosen for each treatment, of which 40 were inoculated with H. fraxineus while 10 seedlings served as control. Three-week-old cultures of HF050 strain of the fungus isolated from the National Park “Biogradska gora”, taken from the mycological collection of the University of Belgrade, Faculty of Forestry, and grown on 3% malt extract agar (Biolab, Hungary; Torlak, Serbia) were used for inoculation. Openings on the bark were made using a sterilized scalp at the same seedling height, and they were inoculated with fragments of mycelium 5×5 mm. Meanwhile, the control seedlings were inoculated with fragments of pure 3% malt extract agar. The inoculated point on the seedling bark were wrapped with Parafilm^® and covered with aluminum foil.

The experiment was completed 50 days after inoculation and 173 days after soil contamination, when 70% of all ash seedlings showed clearly visible symptoms of ash dieback. Seedlings were cut at the level of root collar and the occurrence of dead top and necrotic lesions has been recorded. Dieback was quantified visually based on the occurrence of withered leaves or premature leaf shedding, as well as declined and deformed branches or rachises in the upper third of the crown. Necrotic lesions were measured immediately after peeling of the bark based on discoloration of the cambium. The length of necrotic lesions was measured vertically in accordance with the height of the seedling, while the width of necrotic lesions was measured as the circumference at the largest visible spot of discoloration. The necrotic area was calculated as the area of the ellipse. Re-isolation of the pathogen was attempted from all inoculated seedlings. The seedlings were cut into round sections at several heights along the stem and sections with fresh necrosis and visible difference between necrotic and healthy tissue were used for re-isolations. These parts were first sterilised on the outer surface by wiping with 96% alcohol and 3-5 seconds of exposure to flame of tissue. Then the bark was completely peeled off and the outer tissues were wiped again with 96% alcohol, exposed to flame for a few seconds and placed on 3% malt extract agar.

Statistical methods

Testing the difference in proportions of dieback, the occurrence of necrosis, and re-isolation between different groups of seedlings was performed using the Z-test for proportions. Normality of distribution of necrotic lesion size was tested by Kolmogorov-Smirnov test and homogeneity of variance of the dimensions of necrotic lesions among various soil treatments was tested using Levene’s test. Since the conditions for the application of parametric tests or models were not met, non-parametric tests were applied for further analyses. The Kruskal-Wallis test and Dunn’s post hoc test were used to test for differences in length and width of necrotic lesions caused by H. fraxineus between different soil treatments. The Mann-Whitney U test was used to test for differences in length and width of necrotic lesions between inoculated and control seedlings, as well as between F. excelsior and F. angustifolia seedlings on certain soil treatments. Statistical tests were performed using the software packages SPSS® ver. 26 (IBM, Armonk, NY, USA) and Excel® 2016 (Microsoft Corp., Redwoods, WA, USA).

Effect of soil contamination with cadmium and lead on F. excelsior dieback

The results of Z-test showed that the proportion of F. excelsior seedlings showing dead top and necrotic lesions, and successful re-isolations of H. fraxineus was not significantly different among different soil treatments (Tab. 1, Fig. 2a-f). The average necrotic area of the inoculated seedlings of F. excelsior was 1023.02 mm² in uncontaminated soil, 1736.84 mm² in cadmium-contaminated soil and 1552.24 mm² in lead-contaminated soil. While the average necrotic area was 143.25, 136.59 and 160.14 mm² for control seedlings grown in uncontaminated, Cd-contaminated and Pb-contaminated soil, respectively.

Tab. 1 - Incidence and severity of symptoms caused by Hymenoscyphus fraxineus depending on soil contamination by Cd and Pb on 2-year-old Fraxinus excelsior after 50 days of inoculation. Different letters indicate significant differences (p<0.05) among treatments after Dunn’s post-hoc test.

Treatments	Seedlings (n)			Mean lesion (mm)		Re-isolations freq. (%)
Treatments	Inoculated	With dieback	With necrotic lesions	Length	Width	Re-isolations freq. (%)
Hymenoscyphus fraxineus	40	37 ^a	40 ^a	34.78 ± 22.25 ^a	8.99 ± 1.50 ^a	75 ^a
Hymenoscyphus fraxineus + Cd	40	32 ^a	40 ^a	48.10 ± 21.67 ^b	11.16 ± 3.02 ^b	85 ^a
Hymenoscyphus fraxineus + Pb	40	34 ^a	40 ^a	47.82 ± 25.21 ^b	9.88 ± 2.50 ^ab	85 ^a
Control clean soil	10	0	0	7.11 ± 4.71 ^c	5.10 ± 2.73 ^c	0
Control Cd	10	0	0	6.60 ± 4.70 ^c	5.30 ± 2.87 ^c	0
Control Pb	10	0	0	8.00 ± 4.94 ^c	5.90 ± 2.18 ^c	0

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Fig. 2 - Example of symptoms caused by Hymenoscyphus fraxineus on two-year-old Fraxinus excelsior seedlings: (a) dieback on uncontaminated soil; (b) dieback on cadmium contaminated soil; (c) dieback on lead contaminated soil; (d) necrotic lesions on uncontaminated soil; (e) necrotic lesions on cadmium contaminated soil; (f) necrotic lesions on lead contaminated soil; (g, j) control on uncontaminated soil; (h, k) control on cadmium contaminated soil; (i, l) control on lead contaminated soil.

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The Mann-Whitney U test showed significant differences both in the length (U = 2.500, p < 0.001) and width (U = 141.500, p < 0.001) of necrotic lesions between inoculated and control seedlings. The Kuskal-Wallis test revealed significant differences in the length of necrotic lesions (H = 15.414, p < 0.001) and the width of necrotic lesions (H = 11.915, p = 0.003) caused by H. fraxineus among F. excelsior seedlings grown under different treatments. Similarly, Dunn’s post hoc test showed significant differences in the length of necrotic lesions between different treatments on inoculated F. excelsior seedlings (Tab. 1).

We found significant differences in the length and width of necrotic lesions between F. excelsior seedlings grown on non-contaminated soil and cadmium-contaminated soil (Tab. 1, Fig. 2d, Fig. 2e). Also, there was a significant difference in the length of necrotic lesions while no significant differences were found in the width of necrotic lesions between seedlings grown in uncontaminated soil and lead-contaminated soil (Tab. 1, Fig. 2d, Fig. 2f). Meanwhile, F. excelsior seedlings grown on soils contaminated with cadmium and lead showed no significant differences neither in length nor width of necrotic lesions (Tab. 1, Fig. 2e, Fig. 2f).

Effect of soil contamination with cadmium and lead on F. angustifolia dieback

The Z-test showed that the proportion of F. angustifolia seedlings showing dead top and necrotic lesions, and successful re-isolations of H. fraxineus was not significantly different among different soil treatments (Tab. 2, Fig. 3a-f). In Fraxinus angustifolia seedlings inoculated with Hymenoscyphus fraxineus,

Tab. 2 - Incidence and severity of symptoms caused by Hymenoscyphus fraxineus depending on soil contamination by Cd and Pb on 2-year-old Fraxinus angustifolia after 50 days of inoculation. Different letters indicate significant differences (p<0.05) among treatments after Dunn’s post-hoc test.

Treatment	Seedlings (n)			Mean Lesion (mm)		Re-isolation freq. (%)
Treatment	Inoculated	With dieback	With necrotic lesions	Length	Width	Re-isolation freq. (%)
Hymenoscyphus fraxineus	40	32 ^a	40 ^a	29.70 ± 13.52 ^a	8.08 ± 1.70 ^a	70 ^a
Hymenoscyphus fraxineus + Cd	40	33 ^a	40 ^a	53.69 ± 25.10 ^b	11.63 ± 2.98 ^b	80 ^a
Hymenoscyphus fraxineus + Pb	40	28 ^a	40 ^a	49.18 ± 16.92 ^b	9.60 ± 1.79 ^c	80 ^a
Control clean soil	10	0	0	6.40 ± 4.42 ^c	4.65 ± 3.27 ^d	0
Control Cd	10	0	0	6.36 ± 4.90 ^c	5.20 ± 2.86 ^d	0
Control Pb	10	0	0	6.30 ± 3.53 ^c	5.90 ± 2.18 ^d	0

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Fig. 3 - Example of symptoms caused by Hymenoscyphus fraxineus on two-year-old Fraxinus angustifolia seedlings: (a) dieback on uncontaminated soil; (b) dieback on cadmium contaminated soil; (c) dieback on lead contaminated soil; (d) necrotic lesions on uncontaminated soil; (e) necrotic lesions on cadmium contaminated soil; (f) necrotic lesions on lead contaminated soil; (g, j) control on uncontaminated soil; (h, k) control on cadmium contaminated soil; (i, l) control on lead contaminated soil.

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The average necrotic area was 785.14, 2044.69 and 1514.27 mm² for F. angustifolia seedlings inoculated with H. fraxineus and grown in uncontaminated, Cd-contaminated and Pb-contaminated soil, respectively. As for control seedlings, average necrotic area was 118.54 mm² in uncontaminated soil, 131.94 mm² in Cd-contaminated soil and 130.62 mm² on lead-contaminated soil.

The Mann-Whitney U test showed that significant differences both in the length (U = 0.000, p < 0.001) and width (U = 255.000 180.000, p < 0.001) of necrotic lesions between inoculated and control seedlings. Significant differences were also found in the length (H = 41.292, p < 0.001) and width (H = 40.709, p < 0.001) of necrotic lesions on narrow-leaved ash seedlings (F. angustifolia) grown on different soil treatments after Kruskal-Wallis test. Similarly, Dunn’s post hoc test showed the presence of significant difference in the length of necrotic lesions between different treatments of inoculated seedlings (Tab. 2).

Similarly to F. excelsior, we found significant differences in length and width of necrotic lesions between F. angustifolia seedlings grown on uncontaminated soil and cadmium-contaminated soil (Tab. 2, Fig. 3d, Fig. 3e). Likewise, F. angustifolia seedlings grown in uncontaminated soil showed significant differences in length and width of necrotic lesions compared with those grown in lead-contaminated soil (Tab. 2, Fig. 3d, Fig. 3f). In contrast, no significant difference were detected in the length of necrotic lesions between seedlings grown in soils contaminated with cadmium and lead, while they showed significant differences in the width of necrotic lesions (Tab. 2, Fig. 3e, Fig. 3f).

Comparison of F. excelsior and F. angustifolia dieback on uncontaminated and contaminated soil

We did not found any significant differences in the proportion of seedlings with dieback symptoms (z = 1.6233, p = 0.10524), necrotic lesions (z = 0.000, p = 1.000), and re-isolation of the fungus (z = 0.5008, p = 0.61708) between F. excelsior and F. angustifolia seedlings grown in uncontaminated soil after Z-test. The Mann-Whitney U test showed that there was no significant difference in the length of necrotic lesions (U = 741.000, p = 0.570), while there was a significant difference in the width of necrotic lesions (U = 493.000, p = 0.003) between the two species for seedlings grown on uncontaminated soil (Tab. 1, Tab. 2, Fig. 2d, Fig. 3d).

Likewise, we found no differences in the proportion of seedlings with dieback symptoms (z = 0.2864, p = 0.77182), necrotic lesions (z = 0.000, p = 1.000), and re-isolation of the fungus (z = 0.5885, p = 0.5552) between the two species grown in soil contaminated with cadmium after Z-test. Similarly, no significant differences in the length (Mann-Whitney U = 715.000, p = 0.413) and width (U = 715.500, p = 0.412) of necrotic lesions were found between F. excelsior and F. angustifolia seedlings grown on cadmium-contaminated soil (Tab. 1, Tab. 2, Fig. 2e, Fig. 3e).

The Z-test showed that there is no statistically significant difference between the two Fraxinus species in the proportion of seedlings showing dieback symptoms (z = 1.6064, p = 0.1074), necrotic lesions (z = 0, p = 1), and re-isolation of the fungus (z = 0.5885, p = 0.5552) on lead-contaminated soil. Further, no significant differences in the length (Mann-Whitney U = 691.500, p = 0.296) and width (U = 774.000, p = 0.800) of necrotic lesions were found between F. excelsior and F. angustifolia on lead-contaminated soil (Tab. 1, Tab. 2, Fig. 2f, Fig. 3f).

This study showed the effect of increased cadmium and lead soil contamination on the development of Hymenoscyphus fraxineus in Fraxinus excelsior and Fraxinus angustifolia. The obtained results showed that the dimensions of necrotic lesions significantly increased in the seedlings of both species grown for a short time on soils contaminated with cadmium and lead, as compared to control seedlings grown on uncontaminated soil. Based on the above evidence, the first null hypothesis was rejected, thus supporting the alternative hypothesis of a different development of H. fraxineus between uncontaminated soil and soil contaminated with heavy metals (cadmium or lead).

The uptake of heavy metals from the soil is intensive in F. excelsior to the extent that it can serve as bioindicator of pollution ([2]). The relationships among the host, pathogen and stress caused by heavy metals are complex and involve many different processes which include plant and pathogen mechanisms of tolerance to heavy metals ([13]). In the specific case, the drastic increase of necrotic lesions on seedlings grown on contaminated soil might support the hypothesis that the pathogen is more tolerant to heavy metals than the host, in that heavy metals can provoke a disturbance in the functioning of the plants and a simultaneous stimulation of the fungus. The disturbances could include changes in metabolism and a reduced defence responses of seedlings. On the other hand, the stimulation of the pathogen might be a consequence of the hormetic effect, either due to a milder stress caused by heavy metals or to the larger amount of nutrients obtained from damaged cells. Specific research is needed aimed at elucidating the role played by heavy metals in damaging the physiological processes of ash, thereby resulting in the greater pathogenicity of H. fraxineus.

It has been reported that cadmium and lead show similar negative effects on callus tissue cultures and seedlings of common ash (F. excelsior) in laboratory conditions, and the toxic effect of lead on seedlings is slightly weaker than the toxic effect of cadmium ([30]). Although there are no similar studies on narrow-leaved ash (F. angustifolia), it can be reasonably assumed that the effects of both heavy metals would be similar. The present study on the harmful effects of the interaction of H. fraxineus and heavy metals (cadmium and lead) on seedlings of both ash species showed that cadmium had a slightly greater effect than lead on the expansion of necrotic lesions, although both elements favor the increase of necrosis compared to control soil. Therefore, the second null hypothesis was rejected, and the alternative hypothesis that there is a difference in the effect of cadmium and lead on the H. fraxineus development was accepted.

On the contaminated soil, we found no significant differences in the sensitivity to dieback of these two ash species during the experiment. Thus, the third null hypothesis that there is no differences in the development of H. fraxineus between F. excelsior and F. angustifolia grown on soil contaminated with cadmium or lead was accepted. On uncontaminated soil, the development of H. fraxineus was consistent with most previous studies reporting a high sensitivity to dieback of both ash species ([22], [21], [16], [36], [46]), with F. angustifolia being slightly less sensitive ([39], [11], [32], [35], [12]).

Ash trees growing in forest ecosystems are thought to be more sensitive to dieback than individual trees growing in isolation ([18]). Also, in the case of F. excelsior, higher tree mortality was recorded in plantations than in natural stands ([9]). An increase in the content of cadmium and lead in uncontaminated forests and plantations, as well as the planting of seedlings on soil contaminated with these heavy metals can significantly accelerate ash dieback and thus make it even more difficult to recover ash stands and make it impossible to grow long-term plantations.

Various symptoms are associated to the occurrence of necrosis, such as dieback wilt and cancer ([42]). The greatest activity of necrotic lesions occurs until August ([25]), namely, at the time when trees actively absorb heavy metals from the soil. However, the growth of necrotic lesions is active throughout the year ([5]), which means that necrotic lesions continue to develop even after the vegetation period, when heavy metals are no longer absorbed from the soil. The occurrence of increased necrotic lesions on contaminated soils suggests that a faster mortality of seedlings is expected in longer periods compared to infected seedlings growing on clean soil.

The recovery of plants after stress caused by heavy metals depends on the type and concentration of the elements as well as the length of exposure, but it can be very successful even after severe stress ([8]). For improving the plant recovery process, it is necessary to better understand the relationships between heavy metals (Cd and Pb) and pathogen stimulation. Based on our results, we can hypothesize that the relationship between Cd and Pb concentration and ash dieback symptoms could be linear. Modelling damages in forest ecosystems depending on the increase in concentration of heavy metals Cd and Pb could be a desirable goal. However, in cases of extreme soil pollution, heavy metal remediation measures in ash habitats can mitigate the harmful effect of ash dieback, mainly during regeneration and the initial spread of the pathogen.

Genetic improvement through the selection of genotypes more tolerant to H. fraxineus is a viable way to protect ash tree stands ([26], [12], [43]). Nevertheless, protective measures aimed at directly combating H. fraxineus and/or indirectly at reducing or eliminating the conditions favorable to its diffusion are still necessary ([40]). Based on our results, it is considered that the decontamination of the soil from cadmium and lead can significantly contribute to the survival of ash seedlings in case of infections by H. fraxineus. In particular, soil decontamination is necessary for more sensitive trees and plantings, or where ash dieback shows a faster development. To this end, remediation of soil polluted with cadmium and lead could be carried out by planting understory species having high phytoremediation potential, e.g., Limonium sinuatum ([41]), as well as by the adoption of different management strategies aimed at removing the factors that favor ash dieback ([27]). Moreover, soil composting has been proven helpful to prevent and reduce the intensity of infection ([33]). Therefore, we recommend the above measures to be combined with soil phytoremediation in order to contrast the rapid development of the infection and mitigate its harmful effects in ash trees.

In this study, the effect of soil contamination with cadmium and lead on the development of ash dieback symptoms caused by the fungus Hymenoscyphus fraxineus on two-year-old Fraxinus excelsior and Fraxinus angustifolia seedlings has been investigated for the first time. Soil contamination resulted in an increased size of necrotic lesions on seedlings of both ash species. However, the width of necrotic lesions in F. angustifolia seedlings was higher on cadmium-contaminated soil, though on uncontaminated soil it was slightly smaller than that recorded in F. excelsior.

In summary, the short-term effects of soil contamination with cadmium and lead significantly affect the development of dieback in both ash species and can accelerate the dieback process of infected seedlings. Anthropogenic activities that contribute to the occurrence of Cd and Pb in the soil must be limited in the vicinity of ash habitats and measures aimed at remediation of heavy metals in soil are necessary during regeneration and reforestation in order to reduce future damage caused by infection with H. fraxineus.

The Ministry of Science, Technological Development, and Innovations of the Republic of Serbia has financed the work of the University of Belgrade, the Faculty of Forestry, and the Institute of Forestry, Belgrade. The authors would like to express their gratitude to the Department of Land Reclamation of the University of Belgrade, Faculty of Forestry, for their organizational assistance in preparing the trial. We also thank Ms. Danijela Dunisijević Bojović, Ph.D. Associate Professor, for her useful advice, and Mr. Ivan Milenković, Ph.D. Assistant Professor, for the donation of plastic bags for planting plant material. The authors owe special gratitude to Ms. Biljana Vemić, MSc Geology, for the technical tasks of trial supervision and data processing.

(1)

Adamčikova K, Paitny J, Pastirčáková K (2018). Individual resistance of Fraxinus angustifolia and F. excelsior clones to Hymenoscyphus fraxineus. Journal of Plant Protection Research 58 (3): 227-233.
Gscholar

(2)

Aksoy A, Demirezen D (2006). Fraxinus excelsior as a biomonitor of heavy metal pollution. Polish Journal of Environmental Studies 15 (1): 27-33.
Online | Gscholar

(3)

Bakys R, Vasaitis R, Skovsgaard JP (2009). Patterns and severity of crown dieback in young even-aged stands of European ash (Fraxinus excelsior L.) in relation to stand density, bud flushing phenotype, and season. Plant Protection Science 49 (3): 120-126.
CrossRef | Gscholar

(4)

Baxter E, Cooke LR, Spaans F, Grant IR, McCracken AR (2023). The introduction of Hymenoscyphus fraxineus to Northern Ireland and the subsequent development of ash dieback. Forest Pathology 53 (1): e12789.
CrossRef | Gscholar

(5)

Bengtsson SBK, Barklund Von P B, Stenlind J (2014). Seasonal pattern of lesion development in diseased Fraxinus excelsior infected by Hymenoscyphus pseudoalbidus. PLoS One 9 (4): e76429.
CrossRef | Gscholar

(6)

Bommarez T, Cools N, De Vos B (2021). Heavy metals in forest floors and topsoils of ICP Forests Level I plots. Forest Soil Coordinating Centre of ICP Forests, Report of the Research Institute for Nature and Forest 2021 (5), Research Institute for Nature and Forest, Brussels, Belgium, pp. 120.
Gscholar

(7)

Bouida L, Rafatullah M, Kerrouche A, Qutob M, Alosaimi AM, Alorfi HS, Hussein MA (2022). A review on cadmium and lead contamination: sources, fate, mechanism, health effects and remediation methods. Water 14 (21): 3432.
CrossRef | Gscholar

(8)

Chmielowska-Bak J, Deckert J (2021). Plant recovery after metal stress - A review. Plants 10 (3): 450.
CrossRef | Gscholar

(9)

Coker TLR, Rozsypálek J, Edwards A, Harwood TP, Butfoy L, Buggs RJA (2019). Estimating mortality rates of European ash (Fraxinus excelsior) under the ash dieback (Hymenoscyphus fraxineus) epidemic. Plants People Planet 1 (1): 48-58.
CrossRef | Gscholar

(10)

De Vries W, Bakker DJ (1998). Manual for calculating critical loads of heavy metals for terrestrial ecosystems. Guidelines for critical limits, calculation methods and input data, Report 166, DLO Winand Staring Centre, Wageningen, Netherlands, pp. 173.
Gscholar

(11)

Diminić D, Kajba D, Milotić M, Andrić I, Kranjec J (2017). Susceptibility of Fraxinus angustifolia clones to Hymenoscyphus fraxineus in lowland Croatia. Baltic Forestry 23 (1): 233-243.
Gscholar

(12)

Enderle R, Stenlid J, Vasaitis R (2019). An overview of ash (Fraxinus spp.) and the ash dieback disease in Europe. CAB Reviews 14 (25): 1-12.
CrossRef | Gscholar

(13)

Gajewska J, Floryszak-Wieczorek J, Sobieszczuk-Nowicka E, Matto A, Arasimowicz-Jelonek M (2022). Fungal and oomycete pathogens and heavy metals: an inglorious couple in the environment. IMA Fungus 13 (6): 1-20.
CrossRef | Gscholar

(14)

Grosdidier M, Ioos R, Marçais B (2018). Do higher summer temperatures restrict the dissemination of Hymenoscyphus fraxineus in France? Forest Pathology 48 (4): e12426.
CrossRef | Gscholar

(15)

Gross A, Holdenrieder O, Pautasso M, Queloz V, Sieber TN (2014). Hymenoscyphus pseudoalbidus, the causal agent of European ash dieback. Molecular Plant Pathology 15 (1): 5-21.
CrossRef | Gscholar

(16)

Hauptman T, Ogris N, De Groot M, Piškur B, Jurc D (2016). Individual resistance of Fraxinus angustifolia clones to ash dieback. Forest Pathology 46 (4): 269-280.
CrossRef | Gscholar

(17)

Havrdová L, Zahradník D, Romportl D, Pešková V, Cerny K (2017). Environmental and silvicultural characteristics influencing the extent of ash dieback in forest stands. Baltic Forestry 23 (1): 168-182.
Gscholar

(18)

Heinze B, Tiefenbacher H, Litschauer R, Kirisits T (2017). Ash dieback in Austria - history, current situation and outlook. In: “Dieback of European ash (Fraxinus spp.) - Consequences and Guidelines for Sustainable Management” (Vasaitis R, Enderle R eds). Swedish University of Agricultural Sciences, Uppsala, Sweden, pp. 33-52.
Gscholar

(19)

Hietala AM, Borja I, Solheim H, Nagy NE, Timmermann V (2018). Propagule pressure build-up by the invasive Hymenoscyphus fraxineus following its introduction to an ash forest inhabited by the native Hymenoscyphus albidus. Frontiers in Plant Science 9: 374.
CrossRef | Gscholar

(20)

Kiran X, Bharti R, Sharma R (2022). Effect of heavy metals: an overview. Materials Today: Proceedings 51 (1): 880-885.
CrossRef | Gscholar

(21)

Kirisits T, Matlakova M, Mottinger-Kroupa S, Halmschlager E, Lakatos F (2010). Chalara fraxinea associated with dieback of narrow-leafed ash (Fraxinus angustifolia). Plant Pathology 59 (2): 411-411.
CrossRef | Gscholar

(22)

Kowalski T, Holdenrieder O (2009). Pathogenicity of Chalara fraxinea. Forest Pathology 39 (1): 1-7.
CrossRef | Gscholar

(23)

Lygis V, Prospero S, Burokiene D, Schoebel CN, Marciulyniene Norkute D G, Rigling D (2017). Virulence of invasive ash pathogen Hymenoscyphus fraxineus in old and recently established populations. Plant Pathology 66 (5): 783-791.
CrossRef | Gscholar

(24)

Marçais B, Husson C, Godart L, Caël O (2016). Influence of site and stand factors on Hymenoscyphus fraxineus-induced basal lesions. Plant Pathology 65 (9): 1452-1461.
CrossRef | Gscholar

(25)

Matisone I, Matisons R, Kenigsvalde K, Gaitnieks T, Burneviča N (2018). Seasonal development of lesions caused by Hymenoscyphus fraxineus on young Fraxinus excelsior trees in Latvia. iForest - Biogeosciences and Forestry 11 (1): 17-23.
CrossRef | Gscholar

(26)

McKinney LV, Nielsen LR, Collinge DB, Thomsen IM, Hansen JK, Kjr ED (2014). The ash dieback crisis: genetic variation in resistance can prove a long-term solution. Plant Pathology 63 (3): 485-499.
CrossRef | Gscholar

(27)

Mitchell R, Beaton J, Bellamy P, Broome A, Chetcuti J, Eaton S, Ellis C, Gimona A, Harmer R, Hester A, Hewison R, Hodgetts N, Iason G, Kerr G, Littlewood N, Newey S, Potts J, Pozsgai G, Ray D, Sim D, Stockan J, Taylor A, Woodward S (2014). Ash dieback in the UK: a review of the ecological and conservation implications and potential management options. Biological Conservation 175 (Suppl. 2): 95-109.
CrossRef | Gscholar

(28)

Morkunas I, Wozniak A, Chung Mai V, Rucinska-Sobkowiak R, Jeandet P (2018). The role of heavy metals in plant response to biotic stress. Molecules 23 (9): 2320.
CrossRef | Gscholar

(29)

Nas FS, Ali M (2018). The effect of lead on plants in terms of growing and biochemical parameters: a review. MOJ Ecology and Environmental Sciences 3 (4): 265-268.
Online | Gscholar

(30)

Nawrot-Chorabik K, Sulkowska M, Osmenda M, Mohytych V, Surówka E, Latowski D (2022). The impact of biotic and abiotic stress factors on development of European ash tissue cultures. Forests 13 (1): 59.
CrossRef | Gscholar

(31)

Niekerk LA, Carelse MF, Bakare OO, Mavumengwana V, Keyster M, Gokul A (2021). The relationship between cadmium toxicity and the modulation of epigenetic traits in plants. International Journal of Molecular Science 22 (13): 7046.
CrossRef | Gscholar

(32)

Nielsen LR, McKinney LV, Hietala AM, Kjaer ED (2017). The susceptibility of Asian, European and North American Fraxinus species to the ash dieback pathogen Hymenoscyphus fraxineus reflects their phylogenetic history. European Journal of Forest Research 136 (1): 59-73.
CrossRef | Gscholar

(33)

Noble R, Woodhall JW, Dobrovin-Pennington A, Perkins K, Somoza-Valdeolmillos E, Gómez HL, Lu Y, Macarthur R, Henry CM (2019). Control of Hymenoscyphus fraxineus, the causal agent of ash dieback, using composting. Forest Pathology 49 (6): 429.
CrossRef | Gscholar

(34)

RS Official Gazette (2019). Regulation on limit values of polluting, harmful, and dangerous substances in the soil. Official Gazette of the Republic of Serbia nos. 30/2018 and 64/2019, Belgrade, Serbia, pp. 10. [in Serbian].
Online | Gscholar

(35)

Papić S, Buriánek V, Longauer R, Kudláček T, Rozsypálek J (2018). Phenotypic variability of Fraxinus excelsior L. and Fraxinus angustifolia Vahl under the ash dieback disease in the Czech Republic. Journal of Forest Science 64 (6): 279-288.
CrossRef | Gscholar

(36)

Pastirčáková K, Adamčíková K, Barta M, Paitny J, Hotka P, Sarvašová I, Kádasi Horáková M (2020). Host Range of Hymenoscyphus fraxineus in Slovak Arboreta. Forests 11 (5): 596.
CrossRef | Gscholar

(37)

Pautasso M, Aas G, Queloz V, Holdenrieder O (2013). European ash (Fraxinus excelsior) dieback - A conservation biology challenge. Biological conservation 158 (2): 37-49.
CrossRef | Gscholar

(38)

Pliura A, Lygis V, Marčiulyniene D, Suchockas V, Bakys R (2015). Genetic variation of Fraxinus excelsior half-sib families in response to ash dieback disease following simulated spring frost and summer drought treatments. iForest - Biogeosciences and Forestry 9 (1): 12-22.
CrossRef | Gscholar

(39)

Schwanda K, Kirisits T (2016). Pathogenicity of Hymenoscyphus fraxineus towards leaves of three European ash species: Fraxinus excelsior, F. angustifolia and F. ornus. Plant Pathology 65 (7): 1071-1083.
CrossRef | Gscholar

(40)

Semizer-Cuming D, Finkeldey R, Rostgaard Nielsen R, Kjr ED (2019). Negative correlation between ash dieback susceptibility and reproductive success: good news for European ash forests. Annals of Forest Science 76 (1): 219.
CrossRef | Gscholar

(41)

Sheikh-Assadi M, Khandan-Mirkohi A, Alemardan A, Moreno-Jiménez E (2015). Mycorrhizal Limonium sinuatum (L.) Mill. enhances accumulation of lead and cadmium. International Journal of Phytoremediation 17 (6): 556-562.
CrossRef | Gscholar

(42)

Skovsgaard JP, Thomsen IM, Skovsgaard IM, Martinussen T (2010). Associations among symptoms of dieback in even-aged stands of ash (Fraxinus excelsior L.). Forest pathology 40 (1): 7-18.
CrossRef | Gscholar

(43)

Skovsgaard JP, Wilhelm GJ, Thomsen IM, Metzler B, Kirisits T, Havrdová L, Enderle R, Dobrowolska D, Cleary M, Clark J (2017). Silvicultural strategies for Fraxinus excelsior in response to dieback caused by Hymenoscyphus fraxineus. Forestry 90 (4): 455-472.
CrossRef | Gscholar

(44)

Tyler G (1992). Critical concentrations of heavy metals in the mor horizon of Swedish forests. Technical Report 4078, Swedish Environmental Protection Agency, Solna, Sweden, pp. 38.
Gscholar

(45)

Tóth G, Hermann T, Szatmári G, Pásztor L (2016). Maps of heavy metals in the soils of the European Union and proposed priority areas for detailed assessment. Science of the Total Environment 565 (15): 1054-1062.
CrossRef | Gscholar

(46)

Vemić A, Kerkez-Janković I, Kudláček T, Jung T, Nikolić M, Nonić M, Milenković I (2021). Development of Hymenoscyphus fraxineus on seedlings from different half-sib lines of Fraxinus angustifolia in Serbia. Forest Pathology 51 (4): 227.
CrossRef | Gscholar

(47)

Volke V, Knapp S, Roloff A (2019). Survey of Hymenoscyphus fraxineus in a central European urban area and exploration of its possible environmental drivers. Urban Forestry and Urban Greening 40: 165-173.
CrossRef | Gscholar

(48)

Yadov SK (2010). Heavy metals toxicity in plants: An overview on the role of glutathione and phytochelatins in heavy metal stress tolerance of plants. South African Journal of Botany 76 (2): 167-179.
CrossRef | Gscholar

Authors’ Affiliation

(1)

0000-0001-9195-8967
Department of Forest Protection, Faculty of Forestry, Kneza Višeslava 1, 11030, Belgrade (Serbia)

(2)

0000-0003-4326-3364
0000-0002-4473-1791
Department of Genetics, Plant Breeding, Seed and Nursery Production; Institute of Forestry, Kneza Višeslava 3, 11030, Belgrade (Serbia)

(3)

0000-0001-7416-4647
0000-0002-8736-6771
Department of Forest Establishment, Silviculture and Ecology, Institute of Forestry, Kneza Višeslava 3, 11030, Belgrade (Serbia)

(4)

0000-0003-2336-0255
Department of Forest Protection, Institute of Forestry, Kneza Višeslava 3, 11030, Belgrade (Serbia)

Corresponding author

Vladan Popović
vladanpop79@gmail.com

Citation

Vemić A, Popović V, Miletić Z, Radulović Z, Rakonjac L, Lučić A (2023). Effect of cadmium (Cd) and lead (Pb) soil contamination on the development of Hymenoscyphus fraxineus on Fraxinus excelsior and F. angustifolia seedlings. iForest 16: 307-313. - doi: 10.3832/ifor4322-016

Academic Editor

Daniela Baldantoni

Paper history

Received: Feb 06, 2023
Accepted: Sep 11, 2023

First online: Nov 09, 2023
Publication Date: Dec 31, 2023
Publication Time: 1.97 months

Open Access

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